Response of root dynamics to nitrogen addition and the influencing factors in a Tibetan alpine steppe, China

doi:10.13287/j.1001-9332.202109.002

Abstract

Abstract: A field manipulative experiment was carried out during 2015 and 2016 to examine the changes and influencing factors of root production, turnover rate, and standing crop under different nitrogen (N) addition levels, i.e., 0, 1, 2, 4, 8 and 16 g N·m^-2·a^-1, in a Tibetan alpine steppe. The results showed that root production and standing crop decreased linearly or exponentially with increasing N addition rates. Compared with control, 16 g N·m^-2·a^-1 significantly reduced the two-year average root production and standing crop by 43.0% and 45.7%, respectively. Root turnover rate increased first and then decreased along the N addition gradient, with the maximum appearing under 2 and 4 g N·m^-2·a^-1 treatments for 2015 and 2016, respectively. Results from linear mixed-effects models showed that root starch content was the main factor modulating the N-induced changes in root production and turnover rate, explaining 21.7% and 25.4% of their variations. Root protein content mainly contributed to the variations in standing crop, with an explanation of 20.8% of its variance. Overall, N addition had negative effect on root production and standing crop, and low N promoted while high N inhibited root turnover rate. Root metabolic parameters were the main factors modulating the N-induced changes in root dynamics.

Key words: root production, root turnover, nitrogen deposition, grassland

LIU Yang, PENG Yun-feng, MEN Ming-xin, PENG Zheng-ping, YANG Yuan-he. Response of root dynamics to nitrogen addition and the influencing factors in a Tibetan alpine steppe, China[J]. Chinese Journal of Applied Ecology, 2021, 32(9): 3119-3126.

References

[1] Chen HYH, Brassard BW. Intrinsic and extrinsic controls of fine root life span. Critical Reviews in Plant Sciences, 2013, 32: 151-161
[2] 张秀娟, 吴楚, 梅莉, 等. 水曲柳和落叶松人工林根系分解与养分释放. 应用生态学报, 2006, 17(8): 1370-1376 [Zhang X-J, Wu C, Mei L, et al. Root decomposition and nutrient release of Fraxinus manshurica and Larix gmelinii plantations. Chinese Journal of Applied Ecology, 2006, 17(8): 1370-1376]
[3] Vargas R, Allen MF, Allen EB. Biomass and carbon accumulation in a fire chronosequence of a seasonally dry tropical forest. Global Change Biology, 2008, 14: 109-124
[4] Hobbie SE. Plant species effects on nutrient cycling: Revisiting litter feedbacks. Trends in Ecology and Evolution, 2015, 30: 357-363
[5] Ackerman D, Millet DB, Chen X. Global estimates of inorganic nitrogen deposition across four decades. Global Biogeochemical Cycles, 2019, 33: 100-107
[6] Peng YF, Guo DL, Yang YH. Global patterns of root dynamics under nitrogen enrichment. Global Ecology and Biogeography, 2016, 26: 102-114
[7] Zhou XH, Fei SF, Sherry R, et al. Root biomass dynamics under experimental warming and doubled precipitation in a tallgrass prairie. Ecosystems, 2012, 15: 542-554
[8] Repo T, Domisch T, Kilpelinen J, et al. Dynamics of fine root production and mortality of Scots pine in waterlogged peat soil during the growing season. Canadian Journal of Forest Research, 2020, 50: 510-518
[9] Bai WM, Wang ZW, Chen QS, et al. Spatial and temporal effects of nitrogen addition on root life span of Leymus chinensis in a typical steppe of Inner Mongolia. Functional Ecology, 2008, 22: 583-591
[10] Wang J, Gao YZ, Zhang YH, et al. Asymmetry in above and belowground productivity responses to N addition in a semiarid temperate steppe. Global Change Bio-logy, 2019, 25: 2958-2969
[11] Zhang QB, Zhao JW, Li SY, et al. Fine root turnover characteristics of alfalfa under drip irrigation at different phosphorus levels. International Journal of Agriculture and Biology, 2020, 24: 68-76
[12] 郭大立, 范萍萍. 关于氮有效性影响细根生产量和周转率的四个假说. 应用生态学报, 2007, 18(10): 2354-2360 [Guo D-L, Fan P-P. Four hypotheses about the effects of soil nitrogen availability on fine root production and turnover. Chinese Journal of Applied Ecology, 2007, 18(10): 2354-2360]
[13] Yang YH, Fang JY, Ji CJ, et al. Stoichiometric shifts in surface soils over broad geographical scales: Evidence from China's grasslands. Global Ecology and Biogeography, 2014, 23: 947-955
[14] Peng YF, Li F, Zhou GY, et al. Nonlinear response of soil respiration to increasing nitrogen additions in a Tibetan alpine steppe. Environmental Research Letters, 2017, 12: 024018
[15] 秦书琪, 房凯, 王冠钦, 等. 高寒草原土壤交换性盐基离子对氮添加的响应: 以紫花针茅草原为例. 植物生态学报, 2018, 22(1): 95-104 [Qin S-Q, Fang K, Wang G-Q, et al. Responses of exchangeable base ca-tions to continuously increasing nitrogen addition in alpine steppe: A case study of Stipa purpurea steppe. Chinese Journal of Plant Ecology, 2018, 22(1): 95-104]
[16] Zhang DY, Peng YF, Li F, et al. Trait identity and functional diversity co-drive response of ecosystem productivity to nitrogen enrichment. Journal of Ecology, 2019, 107: 2402-2414
[17] Bai WM, Xun F, Li Y, et al. Rhizome severing increases root lifespan of Leymus chinensis in a typical steppe of Inner Mongolia. PLoS One, 2010, 5(8): e12125
[18] Bai WM, Wan SQ, Niu SL, et al. Increased temperature and precipitation interact to affect root production, mortality, and turnover in a temperate steppe: Implications for ecosystem C cycling. Global Change Biology, 2010, 16: 1306-1316
[19] 白文明, 程维信, 李凌浩. 微根窗技术及其在植物根系研究中的应用. 生态学报, 2005, 25(11): 3076-3081 [Bai W-M, Cheng W-X, Li L-H. Applications of minirhizotron techniques to root ecology research. Acta Ecologica Sinica, 2005, 25(11): 3076-3081]
[20] Peng YF, Li F, Zhou GY, et al. Linkages of plant stoichiometry to ecosystem production and carbon fluxes with increasing nitrogen inputs in an alpine steppe. Global Change Biology, 2017, 23: 5249-5259
[21] 赵轶鹏, 赵新勇. 植物体可溶性糖测定方法的优化. 安徽农业科学, 2018, 46(4): 184-185 [Zhao Y-P, Zhao X-Y. Optimization of classical measuring method of soluble sugar in plant. Journal of Anhui Agricultural Sciences, 2018, 46(4): 184-185]
[22] 郭冬生, 彭小兰. 蒽酮比色法和酶水解法两种淀粉测定方法的比较研究. 湖南文理学院学报, 2007, 19(3): 34-36 [Guo D-S, Peng X-L. Comparative study on antrone chromametry and enzymatic hydrolysis for assay starch method. Journal of Hunan University of Arts and Science, 2007, 19(3): 34-36]
[23] 王红妮, 王学春, 赵长坤, 等. 油菜秸秆还田对水稻根系、分蘖和产量的影响. 应用生态学报, 2019, 30(4): 1243-1252 [Wang H-N, Wang X-C, Zhao C-K, et al. Effects of oilseed rape straw incorporation on root, tiller and grain yield of rice. Chinese Journal of Applied Ecology, 2019, 30(4): 1243-1252]
[24] 李元, 何永美, 祖艳群. 增强UV-B辐射对作物生理代谢、DNA和蛋白质的影响研究进展. 应用生态学报, 2006, 17(1): 123-126 [Li Y, He Y-M, Zu Y-Q, et al. Effects of enhanced UV-B radiation on physiological metabolism, DNA and protein of crops: A review. Chinese Journal of Applied Ecology, 2006, 17(1): 123-126]
[25] LeBauer DS, Treseder KK. Nitrogen limitation of net primary productivity in terrestrial ecosystems is globally distributed. Ecology, 2008, 89: 371-379
[26] Liebig J, Playfair L, Webster JW. Organic chemistry in its applications to agriculture and physiology. North American Review, 1842, 54: 476-483
[27] Chapin FS, Bloom AJ, Field CB, et al. Plant responses to multiple environmental factors. BioScience, 1987, 37: 49-57
[28] Reich PB, Tjoelker MG, Pregitzer KS, et al. Scaling of respiration to nitrogen in leaves, stems and roots of higher land plants. Ecology Letters, 2008, 11: 793-801
[29] Peng YF, Li CJ, Fritschi FB. Diurnal dynamics of maize leaf photosynthesis and carbohydrate concentrations in response to differential N availability. Environmental and Experimental Botany, 2014, 99: 18-27
[30] Burton AJ, Pregitzer KS, Hendrick RL. Relationships between fine root dynamics and nitrogen availability in Michigan northern hardwood forests. Oecologia, 2000, 125: 389-399
[31] Peng YF, Chen HYH, Yang YH. Global pattern and drivers of nitrogen saturation threshold of grassland productivity. Functional Ecology, 2020, 34: 1979-1990
[32] Peng YF, Wang GQ, Li F, et al. Unimodal response of soil methane consumption to increasing nitrogen additions. Environmental Science & Technology, 2019, 53: 4150-4160
[33] Shcherbak I, Millar N, Robertson GP. Global metaana-lysis of the nonlinear response of soil nitrous oxide (N₂O) emissions to fertilizer nitrogen. Proceedings of the National Academy of Sciences of the United States of America, 2014, 111: 9199-9204